MAX24001
2.5Gbps Tx Burst-Mode Laser Transceiver
General D es cription
The MAX24001 is a complete burst-mode laser driver
transmitter and limiting amplifier receiver for use
within fiber optic modules for FTTx applications. A
fully compliant GPON/GEPON module with digital
diagnostics can be realized when used with a 2KB
EEPROM and suitable optics. Alternatively, a
microcontroller can be used in conjunction with the
MAX24001; however, this is not a necessity in order
to achieve SFF-8472 compliance.
The 2.5Gbps limiting receive path features
programmable output swing control, rate selection,
and OMA-based loss-of-signal detection. Functions
are also provided which facilitate the implementation
of APD biasing without the need for an external DC-
DC converter.
The burst-mode laser driver has temperature
compensated modulation control using a lookup
table. Closed-loop control of laser power incorporates
track ing error com pensatio n and has multip le options
for rapidly settling the laser power thus enabling fast
registration and shutdown on the network.
Diagnostics are enhanced with the inclusion of
programmable transmit signal detection during
bursts, and rogue ONU detection between bursts.
This is linked to a laser safety system which allows
the modulation and bias currents to be shut off in
response to a range of different fault conditions
detected on-chip.
The transmit and receive systems are independently
powered and can respond separately to the SLEEP
pin. T he MAX24001 is highl y configur able f rom either
EEPROM or low-cost MCU using a two-wire
interface.
Applications
GPON, GEPON, Gigabit Ethernet
Functional D iagram
Features
2.5Gbps Limiting Receiver
Integrated APD Bias L oop With Overvoltage
And Overcurrent Protection
OMA-Based LOS Detection
1.25Gbps to 2.5Gbps Lase r Driver
CML, LVPECL, HSTL, SSTL-Compatible
Inputs
Open and Closed-Loop Bias Control
Temperature-Compensated IMOD Control
Highly Con figurable Laser Safety System
Transmit TX_SD and Rogue ONU Detection
SFP MSA and S FF-8472 Digital Diagnostics
Integrated Temp erature Sensor
Power-Saving S L EEP Modes
External DAC , ADC, and PWM Interfaces
Order ing Information
PART TEMP RANGE PIN-PACKAGE
MAX24001TL+
-40
°
C to +95
°
C
40 TQFN-EP*
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed pad.
RX_OUT+
RX_OUT-
RX_IN+
RX_IN-
LOS/SD
2.5Gbps Limiting Receiver
TX_IN+
TX_IN- TX_OUT+
TX_OUT-
ADC
TX_FAULT / DAC
BEN+
BEN-
BIAS
MPD
TX_SD /
TX_FAULT
SCL_SLAVE
SDA_SLAVE
SDA_MASTER
SCL_MASTER
RSSI
SLEEP
2.5Gbps Burst mode laser driver
APD_CTRL
TX_DISABLE
TSENSE
TSENSE_RET
19-6460; Rev 2; 2/14 Maxim Integrated 1
Some revisions of this device may incorporate deviations from published specifications known as errata. Multiple
revisions of any device may be simultaneously available through various sales channels. For information about device
errata, go to: www.maximintegrated.com/errata. For pricing, delivery, and ordering information, please contact
Maxim Direct at 1-888-629-4642, or visit Maxim’s website at www.maximintegrated.com.
ABSOLUTE MAXIMUM RATINGS
Voltage Range on VDD_TX, VDD_TXO, VDD_RX, VDD_RXO ........................................................................... -0.3V to +3.65V
Voltage Range on Any Pin Not Otherwise Specified (with respect to VSS_* ) ........................... -0.5V to (VDD_* + 0.5V)
Continuous Power Dissipation (TA = +70°C)
TQFN (derate 35.7mW/°C above +70°C) ................................................................................................. 2857.1mW
Operating Temperature Range ............................................................................................................ -40°C to +95°C
Junction Temperature ...................................................................................................................................... +150°C
Storage Temperature ......................................................................................................................... -70°C to +150°C
Lead Te mperature (soldering, 10s) ................................................................................................................. +300°C
Soldering Temperature (reflow) ....................................................................................................................... +260°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional opera-
tion of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect device reliability.
RECOMMENDED DC OPERATING CONDITIONS
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Operating Supply Voltage VDD
3.0 3.3 3.6 V
RSSI Pin Compliance ROSA sourcing to RSSI pin VDD -
0.75 V
ROSA s inking from RS SI pin 0.75 V
BIAS Pin Compliance 0.8 V
TX_OUT Pin Compliance 0.8 V
MPD Input Current For correct APC loop operation 40 2000 µA
MPD Input Capacitance For correct APC loop operation 4 20 pF
Junction Temperature -40 +120 °C
Case Temperature -40 +95 °C
Device not guaranteed to meet parametric specifications when operated beyond these conditions. Permanent damage may be incurred by
operating beyond thes e limits.
ELECTRICAL CHARACTERISTICS
(VCC = 2.97V to 3.63V, TA = -40°C to +95°C.) (Note 1)
Note 1: Electrical s pecifications are production t ested at T A = +25°C. Specifications over the entire operating temperature range are guaranteed
by design and characterizati on. Typical specifications are at TA = +25°C, 3.3V.
CONTINUOUS RATING S
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Supply Current IDD Excluding laser bias and modulation currents,
20mA bia s and modulation current, Rx CML
output 400mVP-P 136 mA
Maxim Integrated 2
RECEIVER CHAR ACTE RISTICS
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Differential Input Impedance 80 100 120
Maximum Input Data Rate
2.5 Gbps
Minimum Input Data Rate
1.25 Gbps
Input Sensitivity Dif ferential, BER = 1E-10, 2.5Gbps,
PRBS 223-1 pattern 6.5 13 mVP-P
Deterministic Jitter 2.5Gbps, VOUT = 800mVP-P, VIN between
25mVP-P differential and 1000mVP-P 40 psP-P
Random Jitter 2.5Gbps, VOUT = 800mVP-P, VIN between
25mVP-P differential and 1000mVP-P 2.7 psRMS
Output Rise/Fall Times 2.5Gbps, VOUT = 800mVP-P,
VIN = 25mVP-P differential and 1000mVP-P 60 ps
Low-Frequency Cutoff
30 kHz
Output Impedance 1MHz differential 80 100 120
Minimum Output Swing Differential, 4-bit programm abl e (Note 2) 200 240 mVP-P
Maximum Output Swing Differential, 4-bit programm abl e (Note 2) 800 880 mVP-P
Note 2: Measured with 1111111100000000 pattern.
LOSS OF SIGNAL AND RSSI CHARACTERISTICS
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Maximum OMA LOS Assert Time 11 μs
Maximum OMA LOS Deassert Time 11 μs
Maximum LOS Threshold Setting 400 mVP-P
LOS Assert/Deassert Level LOS DAC = 50 (Note 3) 67 mVP-P
LOS DAC = 105 (Note 3) 143 mVP-P
Maximum RSSI Current Level Sourced or sunk from RSSI pin 1200 μA
Note 3: LOS assert and deassert levels can be set independently to define hysteresis.
Maxim Integrated 3
TRANSMI TTER CHAR ACTERI STICS
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Maximum Input Data Rate PRBS23 2.488 Gbps
Minimum Input Data Rate PRBS23 1.25 Gbps
Maximum Modulation Current
80 mAP-P
Minimum Modulation Current
8 mAP-P
Maximum Electrical R ise/Fall Time
(20% to 80%) Measured using 15Ω effective termination,
IMOD = 8mAP-P to 80mAP-P 96 ps
Total Jitter PRBS15, 2.488Gbps, IMOD = 8mAP-P to
80mAP-P, differential electrical
measurement 65 175 mUIP-P
Deterministic Jitter PRBS15, 2.488Gbps, IMOD = 8mAP-P to
80mAP-P, differential electrical
measurement 45 mUIP-P
Random Jitter PRBS15, 2.488Gbps, IMOD = 8mAP-P to
80mAP-P, differential electrical
measurement 1.11 mUIRMS
Maximum Bias Current 90 mA
BURST TIMI NGS
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Burst Enable/Disable Time
(Electrical)
Disable: Bias current reduced t o 20% of its
maximum value.
Enable: Bias current increased to 90% of
desired bias plus modulation current
Target bias current > 3mA
7 12 ns
Minimum Burst Length to Update
APC Loop During closed-loop operat i on 90 ns
Minimum Burst Gap During closed-loop operati on 75 ns
Maximum Initial Mean Power
Control Settling Time (APC Loop)
From power-on, negation of TX_DISABLE,
or negation of SLEEP to 90% of desired
optical power.
Fast settling algori thm enabled, no f ast
start LUT.
Bias current overs hoot < 10%
Bias current > 4mA
1.2 µs
Maxim Integrated 4
TRANSM ITTER INPU T CHARACTERISTICS
Typical I/O ranges for TX_IN and BEN are shown. TX_IN and BEN inputs are also compatible with HSTL and
SSTL for low-voltage operation.
DIGITAL I/O CHARACTERISTICS
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Time To Initialise From power-up or hot plug 71 ms
TX_DISABLE Assert TX_DISABLE assert to optical disable 0.3 μs
TX_DISABLE Negate TX_DISABLE negate to optical enable 0.5 ms
TX_DISABLE to Reset Time TX _DISABLE must be held high to
reset TX_FAULT 0.155 μs
Maximum Delay BEN Change to
TX_SD Response Ri sing or falling edge 100 ns
Light During Gap to Laser
Shutdown Rogue ONU 100 μs
Typical I/O Ranges for SLEEP, TX_DISABLE, LOS and TX_SD
V
V
IH
IL
VDD + 0.1
VDD - 2.0
CML 3V3
VPP (diff)
0.2V 1.6V
TX_IN (differential AC or DC coupled)
BEN (differential DC coupled)
Input
Voltage
Range VIL(max)
LVPECL 3V3
VDD - 1.81
VDD - 1.48
VDD - 1.16
VDD - 0.88
VIL(min)
VIH(max)
VIH(min)
TX_IN (differential AC or DC coupled)
BEN (differential DC coupled)
LVCMOS/LVTTL 3V3
VIL(max)
-0.3
0.8V
2V
VDD
VIL(min)
VIH(max)
VIH(min)
TX_IN (differential AC or DC coupled)
BEN (differential DC coupled)
Maxim Integrated 5
PERIPHERAL FUNCTIONS
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Power-On-Reset (POR ) Voltage
Module 3V3 supply voltage above which
reset will not be asserted 2.5 V
Module 3V3 supply voltage below which
reset is guaranteed 2.2 V
APD Control
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
ADC Pin Minimum Voltage
1.30 V
ADC Pin Max imum Voltage
2.25 V
DAC Pi n Minimum Current 0 mA
DAC Pi n Maximum Current 0.45 mA
DAC Pin Compliance 1.5 V
PWM Frequency Minimum P WM frequency 250 kHz
Maximum PWM frequency 2 MHz
Step Response Settli ng Time Load current change from 20μA to 1mA 2 ms
SLEEP
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Sleep Assert/Deassert Time to allow first operation or enter sleep
from deassertion of sleep pin 100 ns
Maxim Integrated 6
TWO-WIRE INTERFACE CHARACTERISTICS
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Maximum SCL Clock Frequency 400 kHz
Minimum SCL Clock LOW Period tLOW 1200 ns
Minimum SCL Clock HIGH Period tHIGH 600 ns
Minimum Setup Time For A
Repeated START Condition tSU:STA 600 ns
Minimum Hold Time (Repeated)
START Condition tHD:STA 600 ns
Minimum Data Hold Time tHD:DAT 0 ns
Minimum Data Setup Time tSU:DAT 100 ns
Minimum Setup Time for ST OP
Condition tSU:STO 600 ns
Minimum Bus Free Time Between a
STOP and START Condition tBUF 1200 ns
Maximum Rise and Fall Times of
Both SDA and SCL Signals tR, tF 300 ns
Minimum Rise and Fall Times of
Both SDA and SCL Signals tR, tF Cb = capacit ance of a single bus line
Cx = 20 + 0.1 x Cb Cx ns
Maximum Capacitance for Each I/O
Pin 10 pF
t
HD:STA
t
SU:STA
t
HIGH
t
LOW
t
SU:DAT
t
HD:DAT
t
R
t
F
t
SU:STO
t
BUF
SDA
SCL
Maxim Integrated 7
DIGITAL DI AGNOSTICS
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
TEMPERATURE
Reporting Resolution -40°C to +95°C range 0.85 °C/LSB
Maximum Inaccuracy Single-point calibration, external mode ±2 °C
POWER SUPPLY
Reporting Resolution 3.0V to 3.6V range 10 mV/LSB
Maximum Inaccuracy Calibrated, within the supply reporting
range ±3 %
T X BIAS
Reporting Resolution 5mA to 90mA range 0.392 mA/LSB
Maximum Inaccuracy Calibrated, within the Tx bias reporting
range ±10 %
TX POWER
MPD Current Reporting Resolution
mpd_range = 00, 40μA to 200μA 0.78 μA/LSB
mpd_range = 01, 100μA to 800μA 3.125 μA/LSB
mpd_range = 10, 400μA to 2000μA 12.5 μA/LSB
Maximum Inaccuracy Calibrated, within the MPD operating
range ±20 %
RX POWER
RSSI Current Reporting Resolution
0 to 16μA (Note 4) 0.5 μA/LSB
16μA to 206 μA (Note 4) 2.0 μA/LSB
206μA to 1000μA (Note 4) 8.0 μA/LSB
Maximum Inaccuracy 3μA to 25μA, calibrated (Note 4) ±25 %
25μA to 1000μA, calibrated (Note 4) ±10 %
Note 4: rx_rssi_scale = 00 (x1 gain) range and resolution settings can be changed to improve accuracy.
Maxim Integrated 8
Pin Configuration
SLEEP
LOS/SD
VDD_RXO
RX_OUT+
RX_OUT-
VSS_RXO
SDA_SLAVE
SCL_SLAVE
SDA_MASTER
DAC/TX_FAULT
TX_SD/TX_FAULT
APD_CTRL
VSS_RX
RX_IN+
RX_IN-
VDD_RX
RSSI
RREF
VDD_DIG
VSS_DIG
VSS_TXO
TX_OUT-
TX_OUT+
VDD_TXO
BIAS
MPD
TX_DISABLE
SCL_MASTER
TSENSE_RET
TSENSE
VDD_TX
TX_IN+
TX_IN-
VSS_TX
BEN-
BEN+
ADC
VSS_TXO
VSS_RX
VSS_RXO
1
EP
MAX24001
TOP VIEW
1
2
3
4
5
6
7
8
9
10
1211 13 14 15 16 17 18 19 20
30
29
28
27
26
25
23
22
21
24
3940 38 37 36 35 34 33 32 31
TQFN
(5mm x 5mm)
Maxim Integrated 9
Pin Description
PIN NAME DIR TYPE FUNCTION
1 SCL_MASTER O/P LVTTL Two-Wire Interface Clock Connection To EEPROM, with Internal 10kΩ Pullup Resistor
2 SDA_MASTER I/O LVTTL Two-Wire Interface Data Connection To EEPROM, with Internal 10kΩ Pullup Resistor
3 VDD_RXO Analog +3.3V Receiver Out put Power Supply
4 VSS_RXO Analog GND Receiver Output Ground Connection
5 RX_OUT- O/P High S peed Limiting Receiver Inverted Output. 100differential to RX_OUT+.
6 RX_OUT+ O/P High Speed Limiting Receiver Noninverted Output. 100differential to RX_OUT-.
7 VSS_RXO Analog GND Receiver Output Ground Connection
8 LOS/SD O/P LVTTL Loss-Of-Signal Indication. Open drain with external 4.7kΩ to 10k resistor.
9 SCL_SLAVE I/P LVTTL Two-Wire Interface Clock Connection To Host. with external 10kΩ pullup res istor
10 SDA_SLAVE I/O LVTTL Two-Wire Interface Data Connection To Host. with external 10kΩ pullup resistor
11 TX_DISABLE I/P LVTTL Internall y pull ed high to VDD_DIG with a 7.5kΩ resistor
12 TSENSE Analog Analog Temperature Sensor Current Force
13 TSENSE_RET Analog Analog Temperature Sensor Current Return
14 VDD_TX Analog +3.3V Transmitter Power Supply
15 TX_IN- I/P High Speed Transmitter Input Signal Inverted
16 TX_IN+ I/P High Speed Transmitter Input Signal Noninverted
17 VSS_TX Analog GND Transmitter Ground Connection
18 BEN+ I/P High Speed Burst-Enable Noninverted
19 BEN- I/P High Speed Burst-Enable Inverted
20 RREF Analog Analog Connects to External Precision Resistor
21 TX_SD/
TX_FAULT O/P LVTTL Push-Pull Signal Detect Indication. Can be configured as open-drain TX_FAULT
output, pulled high externally using a 4.7kΩ to 10kΩ resistor.
22 MPD I/P Analog Monitor Photodiode Input
23 BIAS Analog Analog Bias Current Sink
24 VSS_TXO Analog GND Transmitter Output Ground Connection
25 TX_OUT+ O/P High Speed Laser Dat a Diff erential Dri ve Output
26 TX_OUT- O/P High Speed Laser Data Differential Drive Output
27 VSS_TXO Analog GND Transmitter Output Ground Connection
28 VDD_TXO Analog +3.3V Transmitter Output Power Supply
29 SLEEP I/P LVTTL Sleep Mode Select
30 VDD_DIG Analog +3.3V Digital Power Supply
31 VSS_DIG Analog GND Digital Ground Connection
32 RSSI I/P Analog Rx Photodiode Monitor (RSSI)
33 VDD_RX Analog +3.3V Receiver Power Supply
34 VSS_RX Analog GND Receiver Ground Connecti on
35 RX_IN- I/P CML Receiver Input Signal. Differential 100Ω with RX_IN+.
36 RX_IN+ I/P CML Receiver Input Signal. Differential 100Ω with RX_IN-.
37 VSS_RX Analog GND Receiver Ground Connecti on
38 ADC I/P Analog Voltage Input to On-Chip ADC
39 DAC/TX_FAULT O/P Analog Current Output For APD Loop Control. Can be configured as open-drain TX_FAULT
output, pulled high externally using a 4.7kΩ to 10kΩ resistor.
40 APD_CTRL O/P LVTTL 3V3 Push-Pull APD Bi as P WM Output. Can be configured as open-drain APD bias
shutdown pin, pulled high externally using a 4.7kΩ to 10kΩ resistor.
EP Analog GND Exposed Pad. Solder to board to provide effective thermal connection to circuit board
Maxim Integrated 10
Detailed Description
Figure 1. MAX24001 Block Diagram
CML
RX_OUT+
RX_OUT-
RX_IN+
RX_IN-
I/P
BUFF
FILTER
LIMIT
PRE-
EMP
LOS/SD
LOS
DAC
2.5Gbps Limiting Receiver
Vcm 50R
50R
rate
invert
TX_IN+
TX_IN- DRIVEPRE TX_OUT+
TX_OUT-
invert
pwadjust
ADC
DAC
BEN+
BEN-
ben
APD
DAC
swing
threshold
0V Vdd
0V Vdd
I/P
interface
0V Vdd
0V Vdd
I/P
interface
DE-
BOUNCE
BIAS
gain
DRIVE
BIAS
DAC
APC
Loop
control
MOD
DAC
mirror
Power
monitor
MPD
Tx Signal
Detect
Laser
safety
TX_SD/
TX_FAULT
Modulation control
modulation
shutdown
fault
/1, /4, /16
/1
SCL_SLAVE
SDA_SLAVE
SDA_MASTER
SCL_MASTER
Registers
And
memory
Host
interface
RSSI
SLEEP
2.5Gbps Burst mode laser driver
APD_CTRL
Diagnostics
And
SFF-8472
APD
Control
TX_DISABLE
TSENSE
TSENSE_RET
Temp
Sensor
target power
invert
apd bias
SINK/
SOURCE
Diag
tracking_adjust
Maxim Integrated 11
Receiver Signal Path
[Control Register Address Range A4h: 90h to 93h]
The signal arriving at RX_IN is terminated with a 100Ω load to minimise return loss. An input buffer adds peaking to
compensate for up to 10mm of FR4. The level of peaking is controlled by the rx_input_peak register. The signal
can also be inverted using rx_invert.
rx_ratesel0 or
rx_ratesel1 BANDWIDTH
(GHz) BIT RATE
(Gbps)
00
1
1.25
01
1.8
2.488
The received signal is then band limited to one of two rates selected by the soft_rate_select bit of the
system_control register (A2h: 7Bh). If soft_rate_select = ‘0’ then select rx_ratesel0 else select rx_ratesel1.
Filter bandwidths are nominally designed to be 0.7x the available data rates.
The CML output stage is a high-current driver that delivers a 200mV to 880mV signal from a low-impedance 50Ω
output. The rx_output_swing register is used to control the signal at RX_OUT with 45mV resolution. Pre-
emphas is m a y also be app l ied t o the outp ut s ig na l usin g rx_preemphasis. The pre-emphasis (def ined as (( B -A)/B)
x 100) can be set to 0%, 2%, 6% or 10%. The pre-emphasis ratio remains relatively constant when A is adjusted.
Figure 2. Rx Pre-Emphasis Control
The CML, pre-emphasis and limiting stages may be automatically powered down under loss-of-signal conditions
(LOS = ‘1 ’) b y settin g the los_squelch r egist er. T his featur e us es th e debou nced LO S signa l pr ior to an y in vers ion
caused by setting los_invert. Alternatively, the CML, pre-emphasis and limiting stages may be directly powered
down by setting the squelch register.
Receiver Loss of Signal (LOS)
[Control Register Address Range A4h: 9Bh to 9Dh]
AB
los_assert
los_deassert
0
1DAC
Debounce
LOS
RX_IN+-
los_raw
Peak
detect los_invert
los_inhibit
Maxim Integrated 12
Figure 3. LOS Detection System
W hen the peak s ignal amplitud e detecte d at RX_IN drops be low the thr eshold le vel set b y los_assert then a loss-
of-signal condition is reported on the LOS pin and the los_deassert threshold is selected. The signal amplitude
must then rise back above the threshold set by los_deassert before the loss-of-signal condition is removed and
the los_assert threshold is re-selected. The two thresholds can be used to introduce a wide range of hysteresis
into LOS detection. The deassert threshold level should be higher than the assert threshold for correct operation.
When the comparator output (los_raw) changes, the los debounce circuit holds the new value at its output for a
programmable period of time controlled by los_debounce. Longer debounce timeout periods may be required to
accommodate the much longer timeframe pulses caused by the response of the TIA AGC when the signal is
suddenly interrupted. The decay of the differential signal is characterized by an unwanted signal crossover as
shown in the diagram below. The unwanted pulse on los_raw is rejected by setting the debounce period to
> 50μs.
Figure 4. LOS Debounce Operation
The los_invert register is used to configure the pin for Signal Detect (SD) instead of LOS. An output mask
(los_inhibit) holds the output to the LOS pin high after power-on reset until the configuration register load from
EEPROM or mic rocontrolle r is com plete. This avoids multiple t ransitions on the LOS pin during i nitializat ion, which
can cause fault conditions to occur at the system level.
Transmitter Signal Path
[Control Register Address Range A4h: 9Eh to A1h]
The input to the transmitter signal path supports CML, LVPECL, HSTL, and SSTL electrical signalling schemes
with a minimum of external components. The input may be either DC or AC coupled. An external 100Ω resistor
provides d ifferential ter mination. T he internal poten tial dividers set the comm on mode level at 2.0V when the input
is AC-coupled.
Figure 5. TX_IN and BEN Input Termination and Signal Conditioning
los_raw
LOS
Debounce timeout period
Received
signal in
Crosses assert
threshold Crosses deassert
threshold
50us typical
TX_IN+
TX_IN-
0V
Vdd
I/P
interface
24k
5k
100R 5k
16k
AC coupled
mode only
0V
Vdd
16k
24k
Maxim Integrated 13
The laser modulation current is controlled by the tx_moddac register with a resolution of 375μA per LSB
(nominally). This register may be set by the host, or alternatively set the modlut_en bit to cause the tx_moddac
register to be automatically refreshed from the modulation lookup table (LUT) every 10ms. The modulation LUT is
stored in external EEPROM at TWI slave address A6h, register address range 80h to FFh. It is indexed using the
upper 7 bits of temperature_uncal.
If the modramp_en re giste r is set then t he va lue in tx_moddac ram ps progr essi vely fr om the old v alue t o the n ew
value by 1 LSB every cycle of the internal 64MHz clock. This prevents glitches from occurring in the DAC. If
ramping is disabled then updates to tx_moddac are ef fective immediately. The m odulation current is switched of f
between bursts and when the laser safety system asserts a shutdown. burst_invert i s used to invert the differential
signal on BEN±. tx_invert is used to invert the polarity of the transmit signal path.
Eye Optimization
The pulse width of the transmitted signal is adjusted by moving the crossing point of the eye up or down using
tx_pwadjust_dir. Use the tx_pwadjust_size to control the amount of adjustment, in the direction set by
tx_pwadjust_dir. At maximum adjustment, the zero crossing point (a) is moved by 40% of the 0-pk eye opening
(b). The tx_pwadjust_hires register can be used to h al ve the adj ustment step size an d thus incr ease r es ol u tion (at
the expense of halving the range).
Figure 6. Cross i ng Poi nt Ad justme nt
The tx_snubber register is used to snub out overshoot or undershoot in the output eye.
Tx Signal Detect
[Control Register Address Range A4h: ADh to AEh, BEh to BFh]
The Tx Signal Detect feature comprises two related areas of functionality:
For external signal and rogue ONU fault detect by the host, the MAX24001 controls the TX_SD pin as follows:
TX_SD = '1' when there is light; TX_SD = '0' when there is no light from the laser.
For on-chip "Rogue ONU f ault detect ", the MAX24001 detects the presenc e of lig ht during the bur st gap. T his f ault
condition is input to the laser safety system which can then optionally shut down the laser within 100μs of light
being detected.
Figure 7. TX_SD Pin Signal Generation
Differential signal is balanced
(tx_pwadjust_size = 000)
0V a
b
Zero crossing point moved up
Width of zero pulses decreases
(tx_pwadjust_dir = 0)
Zero crossing point moved down
Width of zero pulses increases
(tx_pwadjust_dir = 1)
TX_SD /
TX_FAULT
tx_ shutdown
MPD
BEN
Rogue ONU
Fault Detect
Laser
Safety
System
1
0
TX_ SD
Control
tx_fault
Current
threshold
Maxim Integrated 14
The MPD current is compared with a threshold current set by the txsd_threshold register. This determines the
MPD current level at which both TX_SD and rogue ONU are detected.
W hen BEN = ‘0’ the T X_SD log ic trans fers the com parator output dir ectl y throug h to tx_sd. In additi on, th e Rogue
ONU Fault Detect logic transfers the comparator output through to the laser safety system. The
txsd_rogueonu_delay register s pecif ies the del ay (in c ycles of the int ernal 64 MHz c lock ) between th e fall ing edge
of BEN and testing for rogue ONU. The rogue_onu_fault condition is not generated during this time.
When BEN = ‘1’ the TX_SD logic output goes high when the input from the comparator goes high. This state is
latched. The tx_sd signal will then remain high until either the end of the burst, or until the comparator output
remains low for a period of time exceeding the time defined by the txsd_deglitch_period register. This prevents
tx_sd from toggling during a burst due to the pattern sensitivity of the MPD current. (During bias loop fast-start,
tx_sd is held at ‘1’)
Selection between TX_SD and TX_FAULT functionality is governed by the txsd_select register. The txsd_allow
register h olds th e pin high until th e conf iguratio n reg ister loa d from EEPROM (or m icroc ontroller) is com pl ete. This
avoids multiple transitions on the TX_SD pin during initialization.
Maxim Integrated 15
Rogue ONU Behavior
Figure 8. Rogue ONU Timing
TX_SD Behavior
Figure 9. TX Signal Detect Timing
During the g aps the TX _SD logic is transpare nt and the c omparat or output is routed d irectl y through to the TX_SD
pin.
During the bursts:
(A) The TX_SD pin is asserted high when the MPD current first exceeds the threshold.
(B) The TX_SD pin will not toggle in response to short term fluctuations of the MPD current above and below the
threshold (due to the pattern sensitivity of the MPD current).
(C) There is a requirem ent that the TX_SD pin responds within 50ns of the ass ertion of BEN. The MPD current is
settled and the TX_SD circuitry can respond well within 50ns of the start of a burst. However, the MAX24001 will
assert T X _SD high whenev er a sig nal is d etecte d dur ing a lo ng bur ste ven if the s ignal does not appear unti l well
after the initial 50ns.
(D) If the laser s tops outp ut ting lig ht during a burst, then there is a delay before T X_SD goes l o w. T his is nec ess ary
in order to distinguish between the MPD current dipping below threshold due to a run of zeros, and the MPD
current dropping below threshold due to a legitimate loss of signal. The delay is programmable using
txsd_deglitch_period.
(E) If the signal is restored during a burst then TX_SD is asserted high again.
BEN
mpd
I
Comparator threshold
TX_SD
Comparator
output
BEN
mpd
I
(A)
TX_SD (B) (C) (D) (E)
>50ns
Maxim Integrated 16
Laser Biasing
[Control Register Address Range A4h: A2h to A9h]
The bias current is controlled by the tx_biasdac register in one of six oper a tin g modes:
OPERATING
MODE DESCRIPTION tx_biasmode
<2:0>
Open loop, static tx_biasdac onl y changes when it is writte n b y the host 000
Open loop, LUT tx_biasdac is constantly refreshed from values read from a temperature
indexed lookup table (the bias LUT) 001
Closed loop,
natural start
An automatic power control (APC) loop constantly adjusts tx_biasdac in
order to maintain a target laser output power level. tx_biasdac defaults to
near-zero after power-up and then converges naturally on the target level
over a duration of time dictated by the loop bandwidth.
100
Closed loop,
LUT start The APC loop controls tx_biasdac, and tx_biasdac is preloaded from the
bias LUT at power-up. 101
Closed loop,
fast start The APC loop controls tx_biasdac, and a fast-start algorithm is invoked at
power-up to rapidly converge the loop on the target power level. 110
Closed loop,
LUT fast start
The APC loop controls tx_biasdac. tx_biasdac is preloaded from the bias
LUT at power up, and then a fast-start algorithm is invoked to rapidly
converge the loop on the target power level. 111
Operational Overview
The tx_biasmode<2:0> register is a grouping of three individual controls registers:
tx_biasmode<0>: b ias_lut_enable
tx_biasmode<1>: faststart_enable
tx_biasmode<2>: apc_enable
Open-Lo op Operation
Clear the apc_enable register for open-loop operation.
The las er bias current is co ntrolled by the tx_biasdac register with a resolution of 92.5μA per LSB (nominal). This
register m ay be set b y the hos t, or alternat ively set th e bias_lut_enable bit to caus e the tx_biasdac register to be
autom atically refres hed from the bias lookup table (LUT) every 10ms. The bias LUT is stored in exter nal EEPRO M
at TWI slave address A6h, register address range 00h to 7Fh. It is indexed using the upper 7 bits of
temperature_uncal.
If the biasramp_en register is set then th e value in tx_biasdac ram ps progres sively from the old v alue to t he new
by 1 LSB every cycle of the internal 64MHz clock. This prevents glitches from occurring in the DAC. If ramping is
disabled then updates to tx_biasdac are effec tive immedi ate l y.
Maxim Integrated 17
Closed-Loop Operation
Set the apc_enable register for closed-loop operation.
The automatic power control (APC) loop compares a value of laser output power produced by the power monitoring
circuits with a target level set by tx_apc_target. This proportional error value is scaled using the apc_loop_gain
and is then used to adjust the value of tx_biasdac (which has a number of inter nal precision extension bits). The
apc_loop_gain register thus controls the bandwidth of the APC loop.
Since the band width of the loo p is n ot ver y high, it is des irable to se t the tx_biasdac register to a point as clos e as
possible to the target laser power level before the APC loop takes over. This is achieved by preloading the
tx_biasdac register with a value from the bias LUT and/or running a search algorithm (referred to as fast-start).
Thes e actions are both t riggered b y the bias_lut_enable and faststart_enable bits. W hen these b its are set , then
a table lookup or fast-start will occur at the next available opportunity. Once the lookup or fast-start has occurred
then these bits are cleared. The host may therefore re-trigger fast/lut start by resetting bias_lut_enable and
faststart_enable at any time. The bits are also set automatically as follows:
On power-up: tx_biasmode is configured from EEPROM
During SLEEP: The value in faststart_after_sleep is transferred to faststart_enable
The value in bias_lut_after_sleep is transferred to bias_lut_enable
During TX_DISABLE: The value in faststart_after_txdisable is transferred to faststart_enable
The value in bias_lut_after_txdisable is transferred to bias_lut_enable
Thus , the required loop behavior when the l aser is en abled can be i ndependen tly configur ed for r eset, sleep m ode
and tx disable. This is further illustrated in the figure below:
Figure 10. Be hav i or of the tx_biasmode Register in Cl osed-Loop Mode
apc_enable
faststart_enable
bias_lut_enable
0
0
0
1
1
1
1
1
0
1
0
0
Power-on reset
Initialise from EEPROM
Load tx_biasdac from bias LUT
Faststart algorithm is executed
initialising normal operation
LASER ENABLED
1
1
1
1
1
faststart_after_sleep
bias_lut_after_sleep
sleep
1
1
0
1
0
0
normal operation
Faststart algorithm is executed
Bias mode register re-loaded
disabled
Bias mode register re-loaded
1
1
0
1
0
0
Faststart algorithm is executed
normal operation
Load tx_biasdac from bias LUT
1
0
faststart_after_tx_disable
bias_lut_after_tx_disable
Maxim Integrated 18
Fast-Start Algorithm
[Control Register Address Range A4h: AAh to Ach]
Figure 11. Fast-Start Algorithm Timing
During fast-start, the MAX24001 is temporarily reconfigured. The modulation driver sinks a constant current of
IMOD/2 on TX_OUT to represent the contribution made by the signal current to the average power. The power
monitoring circuit is reconfigured to supply a direct comparison between the received MPD current and the target
MPD current . The process of making a change t o bias cur rent and then a subseq uent compar ison of MPD curr ent
and target current is referred to as iteration. An itera tion has a fixed duration (nominally 62ns).
Initially, the bias current is stepped up on every iteration until the MPD current exceeds the threshold. The initial
bias current step size A is ideally ½ the modulation current, the rationale being that this is the largest step which
can be tak en whilst e nsur in g that t he P1 power lev el is not ex c eed ed. Mor e g enerally, the init ia l s tep si ze is defined
as A = (tx_fstart_initial/256) x IMOD.
W hen the t arget l ev el is ex c eeded th e s te p s i ze the n dec a ys (C). Halving the step si ze ev er y it er ation amounts to a
binar y search. In practice, incom plete settl ing of the lo op can resu lt in a sm all overshoot of the target cur rent level .
It is theref ore recomm ended that each step is slightly more than 0.5x the previou s step. This is configura ble using
the fstart_decay register. The fstart_decay regist er deter mines the m ultiplication fact or appl ied t o the s te p size on
each subsequent iteration of the fast-start algorithm.
A
B
C
Target MPD current
D
MPD current
(Laser output power) Bias current
Step size
Maxim Integrated 19
fstart_decay
STEP DECAY
MULTIPLIER
100000
100001
100010
100011
100100
100101
..
101110
101111
32/64 = 0.5
33/64 = 0.516
34/64 = 0.531
35/64 = 0.547
36/64 = 0.563
37/64 = 0.5785
..
46/64 = 0.719
47/64 = 0.734
The direction of each current step depends on whether the measured MPD current is above or below the target
level. The number of iterations B is controlled by the fstart_duration register. The maximum num ber of iterations
which can be guaranteed to complete within 3 x 400ns bursts is 15.
At the end of the fast-start algorithm, the laser output stage switches from sinking DC IMON/2 on TX_OUT to full
amplitude signal. This may result in a brief current spike. A facility is provided to optionally shut down the
modulation current through the laser during this transition period (D). Use the fstart_recovery_en and
fstart_recovery_time registers to shut down the modulation current for 0, 1, or 2 iterations.
APC Loop Bandwidth
The apc_loop_gain register adjusts the gain of the APC control loop. Loop bandwidth (Hz) is calculated as a
function of apc_loop_gain:
apc _loop_gain 15 elec mpd CLOCK
apc _loop_gain 15 8
elec mpd
2 k k (biasdac _lsb 4) f
Bandwidth(Hz) 2 16 mondac _lsb
2 k k 3.02 10
× × × ××
= ×π× ×
= × × ××
Where: mondac_lsb = 0.78μA
biasdac_lsb = 92.5μA
fCLOCK = 64MHz (typical)
kmpd = 0.0625 when mpd_range = 10
0. 2 5 when mpd_range = 01
1 w hen mpd_range = 00
kelec = (MPD current)/(laser current)
apc_loop_gain
GAIN
0000
0001
0010
:
1100
1101
1110
1111
2-15
2-14
2-13
:
2-3
2-2
2-1
1
Maxim Integrated 20
Power Monitoring
A power monitoring circuit generates a digital measure of MPD current (laser power) based on time-averaged
samples taken during bursts when the laser is enabled. It has three settings in order to accommodate the wide
range of monitor photodiode currents. The range setting (mpd_range) is chosen at the time that the module is
calibrated, and does not change during normal operation of the APC loop. The unfiltered, 8-bit digital measure of
MPD current is used internall y by the APC loop.
mpd_range
PD MIRROR
GAIN
I
MON
OPERATING
RANGEA)
00
01
10
1
1/4
1/16
40 to 200
100 to 800
400 to 2000
Track ing error in t he TOSA means that the MPD current m ay var y over tem perature i n a nonl inear wa y for a give n
laser optical power. If the temperature-indexed tracking error lookup table (LUT) is enabled then the digital
meas ur e of MPD c urr en t is m ultiplied b y th e va lues read f rom the L U T . Eac h entry in th e LUT represe nts a num ber
in the range 0.5 (00h) to 1.5 (FFh), and 80h represents unity gain.
Set the trackinglut_en bit to enable th is feature. A correction f actor is retr ieved from the track ing error LUT every
10ms . This LUT is s tored in external EEPRO M at TWI slave addres s A8h, register address range 80h to F Fh. It is
indexed using the upper 7 bits of temperature_uncal.
The digital measure of MP D c urr ent ( incl ud ing tr acking error compensation) is us ed by the APC loo p to c o nt r ol bias
current.
Power Reporting
For power reporting purposes, the power monitor output is low-pass filtered to suppress the pattern sensitivity of
the MPD current. This filter bandwidth is programmable using the mon_bandwidth register. Bandwidth = 64/( x
2(15-n)) where n is the 4-bit integer mon_bandwidth value up to a maximum of 14. The filtered measure of laser
power can be read from the txpower_uncal register.
mon_bandwidth
BANDWIDTH
at fCLOCK = 64MHz
0000
0001
..
1000
..
1110
1111
311Hz
622Hz
..
80kHz
..
5.1MHz
No filtering
The mpd_range should be set at a level which accommodates the expected range of MPD current. The
MAX24001 is not des igned to autom atically range switch during normal APC loop operation. However, if the APC
loop fails and t he power m onitor s aturates then the mpd_range will tem porarily switc h so that po wer reporti ng can
cover the full 0 to 2mA range of photodiode current. The range then recovers back to the original setting if the
power monitor value drops back below 64.
Power Leveling
The power_levelling register implements GPON power levelling. Set to 00, 01, or 1x to reduce the modulation
amplitude set by tx_moddac by x1, x0.5 and x0.25, respectively. This register will also reduce the power level by
having the sam e effect on the out put of the tx_apc_target reg ister. Power leve lling does not af fect the bias cur rent
in open-loop mode.
Maxim Integrated 21
Laser Safety
[Control Register Address Range A4h: AFh to B3h]
The laser safet y system generates t wo sign als, tx_fault_int and tx_shutdown_int. Tx_fault_int is pure
status. It r eports via both re gister a nd T X_FAULT pin whether one or m or e enabled f ault c onditions hav e occ urred.
The TX_FAULT pin can be configured to appear at pin 21 or 39 using pin_config0. Tx_shutdown_int is a
control s ignal. It disa bles the b ias and modul ation currents to the las er when one or more enabled fault conditions
have occurred.
Fault Conditions
The fault conditions which affect tx_fault_int and tx_shutdown_int are:
When the laser is in shutdown then the bias fault condition is ignored by the laser safety system. When
tx_shutdown is deasserted there is a 250μs delay before the bias fault condition is used. This allows the circuit
which detec t a gro und shor t on the bias pin time to s ettle bef ore the bias fault co ndition is seen b y the laser s afety
system.
Architecture
Figure 12. Las er Safe t y Sy s tem
soft_tx_fault
tx_disable_fault
S Q
R
reset
0
1
Latch enable
Fault enable
ls_txfault_faulten<0>
ls_txfault_latchen<0>
laser_inhibit
Cell<0>
tx_disable_fault
bias_fault
vdd_fault
vref_fault
apc_fault
alarm_fault
rogue_onu_fault
tx_fault_pin
tx_fault_int
Fault
conditions Safety
cells
Cell<1>
Cell<2>
Cell<3>
Cell<4>
Cell<5>
Cell<6>
Cell<7>
tx_shutdown_int
Laser safety system (Tx fault)
laser_inhibit
Laser safety system (Tx shutdown)
ls_shutdown_faulten
ls_shutdown_latchen
shutdown
Bias Fault
APC Fault
VREF Fault
VDD Fault
Tx Disable Fault
Soft Tx Fault
RogueOnu Fault
Alarm Fault
This occurs when the BIAS pin is shorted to ground.
This occurs when the MPD pin is shorted to ground.
This occurs when the RREF pin is shorted to ground.
This occurs when brownouts are detected on TX or TXO.
Is given by: (TX _D ISAB LE X O R tx_disable_invert) OR soft_tx_disable where
TX_DISABLE is the pin value and soft_tx_disable is in SFF-8472 status_control.
This occurs when the soft_tx_fault bit in software_faults register is set.
If the laser is on during a gap between bursts then this fault condition is generated.
This occurs when one or more of the SFF-8472 DDM alarm flags are set to ‘1’. The flags
which contribute to Alarm Fault are programmable via ls_alarmflag_en.
Maxim Integrated 22
The laser safet y system (T x fault) gen erates the tx_fault_int signal. The s tatus of this signal c an be acc essed
in the SFF-8472 status_control register. The signal is also multiplexed onto the TX_FAULT/TX_SD pin.
Every saf ety cell has its own pair of latch enable and f ault enable cont rol register bits. T he fault condition c an only
propagate thr oug h to the output when _faulten = ‘1’. W hen _latchen = ‘1’ a latc hed ver sion of the fault con dition is
used. The latch is held in reset when latching is disabled or when the tx_disable_fault signal is asserted.
Note that tx_disable_fault is also a fault condition signal.
W hen it is asserted, the laser_inhibit signal holds all latches in r eset and f orces the tx_fault_int s ignal to ‘1.
Note that after the power-on reset, laser_inhibit is enabled. During initialization pin_config is the last
configuration register to be loaded from EEPROM and therefore has the effect of clearing laser_inhibit and thus
enabling the laser.
ls_fault_status reports the status of the fault conditions at the inputs to the safety cells.
The laser safety system is fully replicated for controlling laser shutdown. The system uses the
ls_shutdown_faulten and ls_shutdown_latchen registers and produces the tx_shutdown_int signal for
disabling the modulation and bias currents. The internal architecture is otherwise the same as the system for Tx
Fault. The shutdown register can be found in hardware_status.
The module Tx supply (VCC_TX) can be used in some applications to shut down the laser. This is supported in
MAX24001 by detecting the removal of VCC_TX on the VDD_TXO pin. VCC_TX is connected to VDD_TXO as shown in Figure
13. A shutdown is then ass erted if the voltag e falls belo w 2.7V. If the conn ection bet ween VCC_TX and VDD_TXO is not
used, VDD_TXO must be connected to another supply.
Figure 13. VDD_TXO Configured to Assert Laser Shutdown
Temperatu r e Senso r
[Control Register Address Range A4h: B6h, B9h, C1h]
The MAX24001 includes an integrated temperature sensor that reports the module temperature at the sensor
transistor. The temp_ext_sensor register selects between an internal transistor or an external PNP transistor
connected to the TSENSE and TSENSE_RET pins. If an external transistor is used then the PCB tracks
connecti ng a n ext ern al PN P tr ans ist or to th e c hip each have resista nc e < < 1. i.e. the tr acks must be k ept as s hor t
as possible. The temperature sensor reports a value in temperature_uncal once every 65ms. Resolution is
approximately 0.8C per LSB of temperature_uncal. Part-to-part accuracy is optimized by adjusting
temp_calibrate until each part reports the same value of temperature_uncal at a common temperature.
Setting leave_pu and tempsense_pu enables the te mperature sens or to be in a power-saving m ode by powering
down between reads.
VCC_TX/VDD_TXO Connection
V
CC_RX
V
CC_TX
TRANSCEIVER IC
V
DD_DIG
2.7V
V
DD
DETECT
V
DD_RX
V
DD_RXO
V
DD_TX
V
DD_TXO
LASER
SAFETY
Maxim Integrated 23
APD Controller
[Control register address range A4h: 94h]
Figure 14. APD Bias ing Applicat io n
Figure 14 shows a simplified arrangement for controlling the APD bias voltage, whereby the FET is switched by a
pulse width modulated signal. The duty cycle can be used to control the voltage across the capacitor. This voltage
can be sampled at the tap point of the potential divider. The MAX24001 provides functions w hich support this
approach.
Figure 15. A PD Bias ing Control Loop Compo ne nts
The PWM frequency can be configured to be 250kHz, 500kHz, 1MHz or 2MHz by pwm_frequency. The 8-bit
value of rx_apdpwm adjusts the duty cycle from 0/256 to 255/256.
The APD controller adjusts the value of rx_apdpwm according to the proportional and integral gain setting of the
loop in re gister s k_proportional and k_integral such t hat the voltage lev el sampled on t he AD C pin con verges on
the target value rx_apd_target. The target value apdlut_en m ay be fixed, or it may be actively refreshed from the
temperature indexed APD lookup table (LUT) when target_lut_enable is set. This LUT is stored in EEPROM at
two-wire slave address A8h, register address range 00h to 7Fh. The LUT is indexed by temperature_uncal.
When the APD controller is active, a limit may be imposed on the maximum PWM duty using max_duty.
APD
_
CTRL
ADC
PWM signal
generator
APD
LUT
ADC
RSSI
APD fault
detect
default
1
current
voltage
rx
_
apd
_
target
PWM P I
controller
APD_CTRL
3.3V
ADC RSSI
Maxim Integrated 24
APD ControllerAdditional features
APD safet y features are al so implem ented. If the sample d value of RS SI current exceeds rx_apd_i_threshold, or
the sam pled voltage on the ADC p in exceeds rx_apd_v_threshold then the APC_CTRL pin dr iver is dis abled (Hi-
Z). Set the thresholds to FFh to disable this feature.
The APD controller is disabled when k_proportional and k_integral are both zero. The value in rx_apdpwm can
be written dir ectl y, or will be per iodic ally r efres hed fr om the APD LUT if pwm_lut_enable is set. The po larit y of the
output on APD_CTRL can be inverted by setting pwm_invert to ‘1’.
If an external control loop is used (for example, using an external DC-DC converter) then this loop could be
controlled by the DAC pin. The DAC is controlled from the rx_apddac register. This will be periodically refreshed
from the APD LUT if dac_lut_enable is set. In this arrangement, the APD_CTRL pin can be used to control the
shutdown input pin of the DC-DC converter.
Digital Diagnostics
Data Generation
[Control Register Address Range A4h: B4h to B5h, E6h to EAh]
Temperature, supply voltage, laser bias current, transmit power, and received power are all periodically sampled.
Temperature
The uncalibrated temperature can be read from the temperature_uncal register.
Supply Voltage
Select between Tx and Rx supply voltages using adc_supplysel, and adjust the sampling rate using
supply_bandwidth. The uncalibrated supply voltage can be read from the supply_uncal register.
Tx Bias Current
The bias current m easured during a burs t will continu e to be reported bet ween bursts , irrespective of the length of
the gap. If the laser is deliberately shutdown by the laser safety system or by asserting TX_DISABLE then Bias
Current reports zero and the low alarm/warning flags are set. The uncalibrated bias current is read from the
bias_uncal register.
Tx Power
The Tx Power meas ured dur ing a b urs t wil l continue to be repor t ed bet ween bursts , irr es pectiv e of the le ngth of the
gap. If the laser is deliberately shutdown by the laser safety system or by asserting TX_DISABLE then Tx Power
reports zero and the low alarm/warning flags are set. The uncalibrated Tx Power is read from the txpower_uncal
register.
Rx Power
The RSSI p in can both sou rce and sink a current ( rx_rssi_sink) which is prop ortiona l to the optical p ower in cident
on the receiver . Resolut ion can be enhanc ed by appl ying additiona l gain (x1, x 1.5 or x2) to the c urrent at the RSSI
pin using the rx_rssi_scale register (see los_rssi_config).
For Rx po wer m easurement, the ADC is use d in nonlinear “3-slo pe” m ode. T his pr ovides bot h wide d ynam ic range
and high resolution at low powers. The uncalibrated, 3-slope encoded value of Rx Power is read from the
rxpower_uncal register.
RSSI CURRENT RANGE A)
rxpower_uncal
GAIN x1
GAIN x1.5
GAIN x2
0 to 16
16 to 208
208 to 1232
0 to 11
11 to 139
139 to 821
0 to 8
8 to 104
104 to 616
0 to 32
32 to 128
128 to 255
Adjust the Rx Power sampling bandwidth using rxpower_bandwidth.
Maxim Integrated 25
Digital Diagnostic Monitors
The raw digit al measures of: temper ature, supp l y v oltage, bias cur re nt, T x Po wer , and R x p ower are con vert ed into
calibrated SFF-8472 Digital Diagnostic Monitor (DDM) values once every 10ms when sff_en is set and the main
loop is acti ve (mainloop _en is set). T hese registers are locat ed in main_c onfig. The follo wing calibratio n constants
are used:
METRIC REFERENCE
SLOPE
(SLA: A4h)
OFFSET
(SLA: A4h)
DDM
(SLA: A2h)
Temperature
Suppl y Voltage
Tx Bias Current
Tx Power
Rx Power
temp
vcc
bias
txpower
rxpower
00h01h
04h05h
08h09h
0Ch0Dh
10h11h (slope 0)
14h15h (slope 1)
02h03h
06h07h
0Ah0Bh
0Eh0Fh
12h13h (offset 0)
16h17h (offset 1)
60h61h
62h63h
64h65h
66h67h
68h69h
All slope values (including Rx power) are stored as 16-bit fixed point (unsigned) as per SFF-8472 external
calibration constants. The slope is calculated as DDM LSB’s per ADC increment, e.g. for supply voltage the slope
unit (bit 8) represents units of 100µA per ADC increm ent (hence the >>8 operation after multiplication).
All offset values (including Rx power) are stored as 16-bit fixed point (signed two’s com plement) as per SFF-8472
external calibration constants. In all cases, the upper by te of the 16-bit word is stored at the lower address.
Rx power has an additional pair of constants to support a rough piecewise linear approximation of the nonlinear
characteristic of received optical power vs. RSSI current. This occurs when a series resistor is used between the
APD and the APD bias voltage generation circuit. It provides a form of compression, protecting the APD by
reducing avalanche gain if current gets too high.
Temperature
Figure 16. Calculating the Temperature DDM
Supply Voltage
Figure 17. Calc u lat in g the Sup ply Vol tag e DD M
Temperature
temperature_uncal
+
x
A2: 60h – 61h
temp_offset
temp_slope
816
Calibrated
SFF-8472 DDM
A/W lookup
>>8
Vcc
supply_uncal
+x
A2: 62h – 63h
vcc_offset
vcc_slope
816
Calibrated
SFF-8472 DDM
A/W lookup
>>8
Maxim Integrated 26
Tx Bias Current
Figure 18. Calc u lat in g the Bias Cur rent DD M
Tx Power
Figure 19. Calc u lat in g the Tx Power DDM
The po wer monitor generat es an 8-b it measure of MP D c urr ent af ter a g ai n of 1, 1/4, or 1/1 6 has been appl i ed. Re-
ranging increases the Tx Power value when gains < 1 have been applied to the MPD current.
txpower_reranged = txpower_uncal << 4 when mpd_range = ‘10’ else
txpower_uncal < < 2 when mpd_range = ‘01’ els e
txpower_uncal
Rx Power
Figure 20. Calc u lat in g the Rx Power DD M
The following formulae are used to convert the 3-slope rxpower_uncal value into a linear pseudo 12-bit (0 to
2448) value:
0 < rxpower_uncal ≤ 32 linearized_rx_power = rxpower_uncal
32 ≤ rxpower_uncal ≤ 128 linearized_rx_power = ((rxpower_uncal 32) x 4) + 32
128 ≤ rxpower_uncal ≤ 255 linearized_rx_power = ((rxpower_uncal 128) x16) + 416
Tx Bias
bias_uncal
+
x
A2: 64h – 65h
bias_offset
bias_slope
816
Calibrated
SFF-8472 DDM
A/W lookup
>>8
Tx Power
txpower_reranged
+
x
A2: 66h – 67h
txpower_offset
txpower_slope
mpd_range
re-range
812 16
Calibrated
SFF-8472 DDM
A/W lookup
>>8
txpower_uncal
Rx Powerrxpower_uncal
+x
A2: 68h – 69h
rxpower_offset
rxpower_slope
Linearise
8 12 16
Calibrated
SFF-8472 DDM
A/W lookup
>>8
Maxim Integrated 27
The s elected pair of slope and of f set values depe nd on the value of linearized_rx_power. If linearized_rx_power
is greater than rxpower_threshold, then use the slope and offset pair from the address range 14h to 17h.
Otherwise use the slope and offset pair from address range 10h to 13h. This coarsely accommodates the
nonlinear ity of the curve of r ec eived opt ic al po wer vs. RSS I curr ent.
Alarm and Warning Flags
Figure 21. Using 8-Bit Calibrated Data to Look Up Alarm and Warning Flags
Figure 22. Al arm and W ar ni ng LUT Mappi ng
The uncalibrated 8-bit diagnostic data values are used to index the alarm and warning LUTs. Construct a LUT by
identifying the required threshold levels in absolute u nits (V, C, mA, µW ) and then reverse the calculations shown
by the figures in the previous section to yield corresponding uncalibrated threshold levels. For Tx and Rx power,
these should incorporate the range and 3-slope encoding, respectively.
The ls_alarmflag_en regis ter controls whic h of the DDM alar m flags c ontribute t o the laser saf ety alarm _fault fault
condition.
A/W LUT1
Temp Supply
A/W LUT2
Bias TxPower
A/W LUT3
RxPower Unused
Alarm high
Alarm low
Warning high
Warning low
76543210
Alarm high
Alarm low
Warning high
Warning low
Alarm high
Alarm low
Warning high
Warning low
76543210
Alarm high
Alarm low
Warning high
Warning low
Alarm high
Alarm low
Warning high
Warning low
76 5 4321 0
Unused
1
1
1
0
0
0
0
0
0
0
:
:
0
0
0
0
0
0
0
0
1
1
1
1
1
1
0
0
0
0
:
:
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
:
:
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
:
:
0
0
1
1
1
1
1
1
00h
FFh
Low alarm threshold
High alarm threshold
High warning threshold
Low warning threshold
Alarm high
Alarm low
Warning high
Warning low
Table indexed using
uncalibrated data
Maxim Integrated 28
Power-Up and Sleep Mode
[Control Register Address Range A4h:8Ch, B8h]
The MAX24001 can be put into a low-p ower mode of operation when t he SLEEP pin is asserted. T his is achie ved
by com bining t he sleep f unc tion with the ch ip-po wer seque ncin g, SLE EP can b e c onfigured t o inde pende ntly af fec t
the Rx and Tx signal paths.
Rx Signal path: The response to the SLEEP pin is controlled by the rx_respond_to_sleeppin register.
Tx Signal path: The response to the SLEEP pin is controlled by the tx_respond_to_sleeppin register.
Figure 23. Conditions for Moving In and Ou t of Slee p Mode
The device will only move between these states when power sequencing is enabled (tx_powerup_en and
rx_powerup_en are set).
The host can alternatively put the MAX24001 to sleep using the tx_force_sleep and rx_force_sleep registers.
ON
SLEEP pin asserted AND responding to sleep pin
REDUCED
POWER
SLEEP pin not asserted
OR
(SLEEP pin asserted AND not responding to sleep pin)
Maxim Integrated 29
Initialization and Control
Overview
The MAX24001 is norm ally used in conjunction w ith a 2k byte EEPROM.
Figure 24. Address Map
Normal Operation
During initia lization, data is transferred from EEPROM areas with TWI slave addresses A0h and A2h into shadow
areas of memory on the MAX24001. Device configuration data is transferred from area A4h into MAX24001
registers.
During normal operati on, the MAX24001 h as ex c lusi ve ac ces s to the lookup tables held in EE PRO M usin g th e TWI
master interface. The MAX24001 TWI slave interface only decodes slave addresses A0h and A2h, and when the
host accesses these areas it is accessing the shadowed memory on the MAX24001. The diagnostic data in the
memory is regularly refreshed.
Using a Microcontroller
If the initializatio n fails, then the MAX24001 defaults to a state whereby the Tx and Rx paths are not enabled, the
main loop is off, and all memory areas are accessible. A microcontroller may then upload data to registers and
control the operation of the MAX24001.
Module Setup
To access EEPROM (cf initialisation_status and system_control registers)
Clear mainloop_en. This stops the main loop.
Wait until eeprom_dma_idle is set. Accesses to EEPROM have then ceased.
Set external_access to direct accesses via the TWI slave interface to EEPROM.
All regions of the EEPROM may then be accessed as long as the chip is in security level 2.
Access Control
[Control register address range A2h: 7Ch to 7Fh, and A4h: 82h to 8Bh]
SFP
MSA
Serial ID
Reserved
SFF8079
0
FFh
A0h
Diagnost.
(external
Cal)
User
EEPROM
A2h
APD
LUT
A4h
Modulation
LUT
A6h A8h
A/W
LUT1 A/W
LUT2 A/W
LUT3
AAh ACh AEh
Bias
LUT
Tracking
LUT
UpperLower
EEPROM
MAX24001
Memory
areas
MAX
24001
registers
MAX
24001
Config/
Control
MAX
24001
(Internal
Cal)
MemoryMemory
Maxim Integrated 30
Three levels of security are defined. The security level determines which areas of EEPROM and register space
may be acces s ed v ia th e t wo-wir e inter f ac e. The securit y level is s electe d by the password_entry register and can
be read from the security_level register in system_status.
Level2 – (password_entry value m atc hes password2). T he host has full rea d and write ac cess to all address
spaces. ( pas s word2 has prior it y over password1).
Level1 (password_entry value m atches password1). The host has read and write access to A0h and A2h
only, as defined by the upper nibbles of the password_configA0 and password_configA2 registers.
Level0 (password_entry value matches neither password1 nor password2). The host has read and write
access to A0h and A2h only, as defined by the lower nibbles of the password_configA0 and
password_configA2 registers.
Password1 and password2 can only be written in level2. The security level will not change when writing a new
value to password2. T ypicall y acces s in lev el 0 is m ore restr ictive t han ac cess in level 1. Read and write ac ces s to
A2h:78h to 7Fh is alw a ys per mitted. If acc es s is denie d the n th e t rans ac t ion is d is car ded i n th e c ase of a write, an d
returns F Fh in the c ase of a read. Duri ng burst-mode acc esses , acces s perm iss ion and destin ation are test ed on a
byte-by-byte basis.
Maxim Integrated 31
Initialization Sequence
[Control register addresses A4h: 80h, 81h, 8Ch, E0h]
Figure 25. Initia liza tio n Seq uenc e
The data integrity bytes are the first two bytes to be read from EEPROM (addresses A4: 80h to 81h). If
data_integrity0 = C3h and data_integrity1 = 5Ah then it is inferred that the EEPROM is correctly programmed
and initiali zation continues.
If the read ac c ess f ails ( no EEPROM) the n eeprom_unresponsive is set. I f the read acc ess s uc ceeds but the data
integrity values are incorrect then eeprom_data_invalid is set. In both cases the transfer from EEPROM is
aborted to prevent MAX24001 defaults from being overwritten with random data. The Tx and Rx paths will not
power up and the MAX24001 will remain in the wait state at the start of the main loop.
The data integrity values only exist in EEPROM. They have no corresponding registers.
Transfer remaining data from
EEPROM to registers and
on-chip memory:
Register data: A4: 90h – BFh
Cal constants: A4: 00h – 17h
Serial ID: A0: 00h – FFh
Digital Diag: A2: 00h - 77h
A2: 80h - FFh
PoR
Transfer data from
EEPROM to registers
A4: 80h – 8Fh
During this time the TWI slave interface is disabled.
If the transfer fails then the eeprom_unresponsive register bit is set
If the content of the data_integrity registers is invalid then the
eeprom_data_invalid register bit is set
Wait until: tx_powerup_en = tx_powerup_done.
And rx_powerup_en = rx_powerup_done
Conditionally power
up the Tx and Rx
paths.
OK?
y
n
Wait for 10ms.
Reset timer.
OK if eeprom_unresponsive = ‘0’ and eeprom_data_invalid = ‘0’
Main loop
Maxim Integrated 32
Main Operating Loop
[Control register address A4h: B7h]
Figure 26. Main Op erati ng Loop
The modulation, bias, APD, and tracking error LUTs are all 128 bytes and indexed by the upper 7 bits of the
uncalibrated temperature sensor output (temperature_uncal). Typically, LUT entry 14h corresponds with a
temperature of -40°C. LUT resolution is then 1.6°C between consecutive table entries. These values are
approximate and may vary slightly from batch to batch.
Wait for 10ms timer
to expire.
Reset
timer
Modulation look-up
Tracking error lookup
Bias look-up
APD look-up
Conditional – Only do this if modlut_en = 1
Conditional – Only do this if biaslut_en = 1
Conditional – Only do this if apdlut_en = 1
Conditional – Only do this if trackinglut_en = 1
Trigger SFF-8472
calibration
On first pass, clear
laser_inhibit All lookups performed before laser is enabled
Conditional – Only do this if sff_en = 1
mainloop_en
= 1?
y
n
Alarm/Warn look-up
Conditional – Only do this if sff_en = 1
Main loop
Maxim Integrated 33
Two-Wire Interface (TWI) Protocol
The SD A_SL AVE a nd S CL _SLAV E pins are ref erred t o as the s lave t wo-wire interf ace ( slave TW I). The s lave TW I
provides ex tern al ac c es s to bot h regis ters within th e MAX24001 and to an y dev ice c onnec ted to th e SCL _M A STER
and SDA_MASTER pins (the master TWI). Typically, an EEPROM is connected to the master TWI.
Framing and Data Transfer
The two-wire interface comprises a clock line (SCL) and a data line (SDA).
An individu al transactio n is framed by a START condition and a ST OP condition. A START condition occur s when
a bus master pulls SDA low while SCL is high. A STOP condition occurs when the bus master allows SDA to
transition low-to-high when SCL is high. Within the frame the master has exclusive control of the bus. The
MAX24001 supports Repeated START conditions whereby the master may simultaneously end one frame and
start another without releasing the bus by replacing the STOP condition with a START condition.
W ithin a fram e the stat e of SDA on ly chan ges when S CL is low. A data b it is tr ans ferr ed on a lo w-to-high transition
of SCL. Data is arranged in packets of 9 bits. The first 8 bits represent data to be transferred (most significant bit
first). The last bit is an acknowledge bit. The recipient of the data holds SDA low during the ninth clock cycle of a
data packet to acknowledge (ACK) the byte. Leaving SDA to be pulled high on the ninth bit signals a not-
acknowledged (NACK) condition. The interpretation of the acknowledge bit by the sender depends on the type of
transactio n and the nat ure of the byte bein g received . SDA is bidirec tional so th at the m aster m ay send data b ytes
during write transactions and the slave may send data bytes during reads.
Device Addressing
The first byte to be sent after a START condition is a slave address byte. The first seven bits of the byte contain the
target slave address (MSB first). The eighth bit indicates the transaction type ‘0’ = write, ‘1’ = read. Each slave
interface on the bus is assigned a 7-bit slave address. If no slave matches the address broadcast by the master
then SDA will be left to be pulled high during the acknowledge bit and the master receives a NACK. The master
must then assert a STOP condition. If a slave identifies the address then it acknowledges it by pulling SDA low.
The master then proceeds with the transaction identified by the type bit.
The two-wire interface of the MAX24001 decodes slave addresses A0h to AFh.
Figure 27. Address Decoding Example
Write Transaction
Figure 28 shows an example of a write transaction. The address byte is successfully acknowledged by the slave,
and the t ype bit is s et low to signif y a write tr ansaction . After the first acknowledg e the master sends a single data
byte. All signalling is controlled by the master except for the SDA line during the acknowledge bits. During the
acknowledge cycle the dire ction of the SDA line is re v er sed and t he s la v e pu lls S DA l o w to ret ur n a ‘0’ ( AC K ) to the
master.
msb
75
643210
lsb
START ACK STOPR/W
ADDRESS
SDA
SCL
Maxim Integrated 34
Figure 25. Write Transaction
The MAX24001 inter prets the f irst data b yte as a register address. This is used t o set an inter nal memor y point er.
Subsequent data bytes within the same transaction will then be written to the memory location addressed by the
pointer. The pointer is autoincremented after each byte. There is no limit to the number of bytes which may be
written in a single burst to the internal registers of the MAX24001.
Read Transaction
Figure 26. Read Transaction
Figure 29 shows an example of a 2-byte read trans act ion. The slave addr es s byte is succ es s f ully ack now ledged by
the slave, and the type bit is set high to signify a read. After the ACK the slave returns a byte from the location
identified by the internal memory pointer. This pointer is then auto-incremented. The slave then releases SDA so
that the m aster c an ACK the b yte. If the s lave receives an ACK th en it will sen d anoth er byte. T he m aster identifies
the last byte by sending a NACK to the slave. The master then issues a STOP to terminate the transaction.
Thus , to im plement a random acc es s read tr ansac tion , a wr ite must first be is sued b y the master containin g a s lav e
address byte and a si ngl e data b yte ( th e reg is ter a ddr es s ) as s hown i n Fi gur e 28. T his s ets up th e memor y pointer.
A read is then sent to retrieve data from this address (see Figure 29).
71
START ACK STOP
SDA
SCL
43 2 1 0W 765
msb
ACK
SDA
direction to slave from slave
71
START ACK STOP
SDA
SCL
R
NACK
SDA
direction to slave from slave
7070
ACK
Maxim Integrated 35
Register Descriptions
For registers containing a single 8-bit field, the MSB of the field is stored in bit 7 of the register byte. Note that
‘reserve d’ r eg is ter b its are specif ied as read on ly. Thes e regis t ers s houl d not be c hange d f r om their power-on reset
(POR) default settings. Register types are:
R
Bit is read on l y via the s la ve TWI. Writing to this bit will ha ve no ef f ec t. The value m ay be changed by
the MAX24001 to communicate operating status to the host.
R/W
Bit is readable and writable via the slave TWI. The value will not be changed by the device itself
except under a device reset.
E
Event bit. This bit is set to ‘1’ by the MAX24001 when a specified event occurs. It is only cleared to ‘0’
when the h ost writes ‘1’ to it via the s la ve TW I. W riting a zero to th is regis ter has no ef fec t. This bit is
also readable.
Slave Address: A2h
6Eh status_control St atus and control informat i on (cf. sff-8472 specification)
BIT FIELD NAME TYPE POR DESCRIPTION
7 tx_disable_state R/W 0 State of the TX_DISABLE pin
6 soft_tx_disable R/W 0 1: Disable the laser
5
4 p_down_status R State of the SLEEP pin
3 P_down_control R/W 0 1: Assert SLEEP
2 tx_fault_state R State of the TX_FAULT pin
1 rx_los_state R State of the LOS/SD pin
0 data_ready_bar R 1 Changes t o ‘0’ when the transceiver is powered up and data is ready
7Ah system_status Additi onal vendor speci f ic status made available to the user irrespective of security
level
BIT FIELD NAME TYPE POR DESCRIPTION
7
6 rogue_onu E 0 1: Rogue_onu condit i on is detected
5 excessive_bias R 0 1: Bias DAC exceeds tx_bias_threshold
4 eeprom_dma_idle R 0 1: EEPROM is idle and may be accessed
3 eeprom_data_invalid R 0 1: Data integrity check failed during initialization
2 eeprom_unresponsive R 0 1: EEPROM failed to ACK the slave address during initi alization
1–0 security_level R 10 00h = level0, 01h = level1, 10h = level2
Maxim Integrated 36
7Bh system_control Additional vendor specific control bits made availabl e to the user irrespecti ve of
security level
BIT FIELD NAME TYPE POR DESCRIPTION
7–6 Undefined
5-4 power_levelling R/W 00 GPON power levelling: 00: x1, 01: x0.5, 1x: x0.25
3 soft_rate_select R/W 0 0: ratesel0 control rx filter, 1: ratesel1 controls rx filter
2 tx_force_sleep R/W 0 1: Force Tx system into low-power SLEEP mode (if respond_to_sleep pin set)
1 rx_force_sleep R/W 0 1: Force Rx system into low-power SLEEP mode
0 external_access R/W 0 Host access routing: 1: EEPROM, 0: internal registers/memory
7Ch password_entry0 R/W 00h Write to this register to select the securit y level .
Level 2 if password_entry = password2 else
Level 1 if password_entry = pas sword1 else
Level 0
7Dh password_entry1 R/W 00h
7Eh password_entry2 R/W 00h
7Fh password_entry3 R/W 00h
Slave Address: A4h
82h password1_0 R/W 00h
Holds the securit y level 1 password.
83h password1_1 R/W 00h
84h password1_2 R/W 00h
85h password1_3 R/W 00h
86h password2_0 R/W 00h
Holds the securit y level 2 password
87h password2_1 R/W 00h
88h password2_2 R/W 00h
89h password2_3 R/W 00h
8Ah password_configA0 Enables the access to the upper and lower halves of the A0h address space to be
configured for s ecurity levels 0 and 1
BIT FIELD NAME TYPE POR DESCRIPTION
7 level1_write_upper R/W 1 1: Write access to upper half of A0h permitted in security level 1
6 level1_read_upper R/W 1 1: Read access to upper half of A0h permitted in security level 1
5 level1_write_lower R/W 1 1: Write access to lower half of A0h permitted in security level 1
4 level1_read_lower R/W 1 1: Read access to lower half of A0h permitted in security level 1
3 level0_write_upper R/W 0 1: Write access to upper half of A0h permitted in securit y level 0
2 level0_read_upper R/W 0 1: Read access to upper half of A0h permitted in securit y l evel 0
1 level0_write_lower R/W 0 1: Write access to lower half of A0h permitted in security level 0
0 level0_read_lower R/W 1 1: Read access to lower half of A0h permitted in security level 0
Maxim Integrated 37
8Bh password_configA2 Enables t he access to the upper and lower halves of the A2h address space to be
configured for security levels 0 and 1
BIT FIELD NAME TYPE POR DESCRIPTION
7 level1_write_upper R/W 1 1: Write access to upper half of A2h permitted in security level 1
6 level1_read_upper R/W 1 1: Read access to upper half of A2h permitted in security level 1
5 level1_write_lower R/W 1 1: Write access to lower half of A2h permitted in security level 1
4 level1_read_lower R/W 1 1: Read access to lower half of A2h permitted in security l evel 1
3 level0_write_upper R/W 0 1: Write access to upper half of A2h permitted in security level 0
2 level0_read_upper R/W 0 1: Read access to upper half of A2h permitted in securit y l evel 0
1 level0_write_lower R/W 0 1: Write access to lower half of A2h permitted in security level 0
0 level0_read_lower R/W 1 1: Read access to lower half of A2h permitted in security level 0
8Ch initialization_config Early stage chip configuration at the start of the initialisat i on process
BIT FIELD NAME TYPE POR DESCRIPTION
7 Undefined
6 R/W 0 Reserved
5 tx_powerup_en R/W 0 1: Enable automatic power-up sequencing for the Tx system
4 rx_powerup_en R/W 0 1: Enable automati c power-up sequencing for the Rx system
3–0 R/W 0111 Reserved
90h rx_input Configures the input buffer of the receive path and sets the receiver bandwidth
BIT FIELD NAME TYPE POR DESCRIPTION
74 rx_input_peak R/W 0000 0000: no peaking, increasing to 1111 for maximum peaking
32 rx_ratesel1 R/W 11 Sets the receiver bandwidth: 00: 1.25Gbps
01: 2.488Gbps
Register is selected by soft_rate_select.
10 rx_ratesel0 R/W 00
92h rx_output Configures the output stage of the receive path
BIT FIELD NAME TYPE POR DESCRIPTION
7 Undefined
6 los_squelch R/W 1 1: Power down RX_OUT when LOS = 1
5 Squelch R/W 0 1: Power down RX_OUT (but only if los_squelch = ‘0’)
4 rx_invert R/W 0 1: Invert signal on RX_OUT
3–0 R/W 0000 Reserved
Maxim Integrated 38
93h rx_driver Controls the output amplitude and pre emphasis on RX_OUT
BIT FIELD NAME TYPE POR DESCRIPTION
7–6 Undefined
5–4 rx_preemphasis R/W 00
Sets pre-emphasis ratio:
00: 0%
01: 2%
10: 6%
11: 10%
3–0 rx_output_swing R/W 1010
Sets output voltage swing:
0000: 200mVP-P
1111: 880mVP-P
Step size is 45mV
94h rx_apd_control Configuration of the APD system and specifically the APD_CTRL and DAC
outputs
BIT FIELD NAME TYPE POR DESCRIPTION
7–6 pwm_frequency R/W 00 0: 250kHz, 1: 500kHz, 2: 1MHz, 3: 2MHz
5 pwm_invert R/W 0 1: invert, 0: normal
4 high_v R/W 0 AP D_CTRL output , 0: open, 1 : 3.3V driver
3 R/W 1 Reserved
2 target_lut_enable R/W 0 1: Load the rx_apd_target register periodically from the APD LU T
1 pwm_lut_enable R/W 0 1: Load the rx_apdpwm register periodically from the APD LUT
0 dac_lut_enable R/W 0 1: Load the rx_apddac register periodicall y from the APD LUT
95h rx_apd_pi Gain values for APD proportional-integral controller
BIT FIELD NAME TYPE POR DESCRIPTION
7–6 max_duty R/W 00
Duty-cy cle limit (maximum): 0: 207/256
1: 223/256
2: 239/256
3: 255/256
5–3 k_integral R/W 000
Integral gain of PI controller (rx_apdpwm LSBs/LSB of error value).
0: 0 4: 2-5
1: 2-8 5: 2-4
2: 2-7 6: 2-3
3: 2-6 7: 2-2
The error value is the difference between the sampl ed APD voltage and the
rx_apd_target value. Eg. If k_integral = 6 and error value = +2 then the
rx_apdpwm register will be increm ented by 2 x 2-3 = 0.25. (Note that the
rx_apdpwm register is the integer part of a fixed point register with 8 additi onal
bits of precision. )
2–0 k_proportional R/W 000
Proportional gai n of PI controller (rx_apdpwm LSBs / LSB of error value):
0: 0 4: 23
1: 20 5: 24
2: 21 6: 25
3: 22 7: 26
96h rx_apd_v_threshold TYPE POR While the APD voltage exceeds this threshold, APD_CTRL is three-stated. Not e
that a threshold of FFh amounts to turning off this feature.
R/W FFh
Maxim Integrated 39
97h rx_apd_i_threshold TYPE POR W hile the APD current exceeds this threshold, APD_CTRL is three-stat ed. Note
that a threshold of FFh amounts to turning off this feature.
R/W FFh
98h rx_apddac TYPE POR Sets the APD DAC output current from 0 to 500μA.
R/W 00h
99h rx_apdpwm TYPE POR Sets the PWM duty cycle in the range 0/256 to 255/256
R/W 00h
9Ah rx_apd_target TYPE POR Sets the target voltage of the APD controller.
R/W 00h
9Bh los_rssi_config Sets the los debounce period and LOS polarity. This register also contains bits
used to control current on RSSI pin
BIT FIELD NAME TYPE POR DESCRIPTION
7 Undefined
6–4 los_debounce R/W 000
000 = 0μs 100 = 64μs
001 = 16μs 101 = 80μs
010 = 32μs 110 = 96μs
011 = 48μs 111 = 112μs
3–2 rx_rssi_scale R/W 11
Sets gain applied to current fl owing through RSSI pin.
00: x1 : RSSI current range 0 to 1275μA
01: x1.5: RSSI current range 0 to 850μA
10: x1.5: RSSI current range 0 to 850μA
11: x2: RSSI current range 0 to 638μA
1 rx_rssi_sink R/W 1 1: Current flows into RSSI pin, 0: Current flows out of RSSI pin
0
9Ch los_assert TYPE POR Sets threshold at which LOS is asserted
R/W 00h
9Dh los_deassert TYPE POR Sets threshol d at which LOS is deasserted
R/W FFh
Maxim Integrated 40
9Eh tx_input Configures the input circ uitry of the transmit path. P ulse width of the transmitted
signal is adjusted by moving the crossi ng point of the eye up or down.
BIT FIELD NAME TYPE POR DESCRIPTION
7 burst_invert R/W 0 1: Invert differenti al signal on BEN
6 tx_invert R/W 0 1: Invert differenti al signal on TX_IN
5 Undefined
4 tx_pwadjust_hires R/W 0 1: Reduce step size of pulse width adjust by half
3 tx_pwadjust_dir R/W 0 0: Move crossing point of eye up, 1: Move crossing point down
2–0 tx_pwadjust_size R/W 000 000: No adjustment, 111: Maximum adjustment. At maximu m adjustment the
zero-cross i ng poi nt moved by 40% of 0-pk eye opening.
A0h tx_output This register is used for managing the quality of the output eye
BIT FIELD NAME TYPE POR DESCRIPTION
7 modramp_en R/W 1 1: DAC ramps from old value to new, 0: immediate step change
6–4 tx_snubber R/W 000 Adjust this to improve rise time and pulse width distortion
3–0 R/W 0000 Reserved
A1h tx_moddac TYPE POR Sets the CML output current for the laser driver (modulation current)
R/W 00h
A2h tx_bias The mpd_gain regist er applies gain to the MPD current. It does not change during
normal operation and therefore the range must be selected to accommodate all
expected values of MPD current.
BIT FIELD NAME TYPE POR DESCRIPTION
7 R/W 0 Reserved
6 Undefined
5–4 mpd_range R/W 10 10: 400μA to 2000μA
01: 100μA to 800μA
00: 40μA to 200μA
3 biasramp_en R/W 1 1: Bias DAC ramps f rom old to new, 0: Immediate step change
2–0 Undefined
A3h tx_biasmode
BIT FIELD NAME TYPE POR DESCRIPTION
7 faststart_after_sleep R/W 0 1: Trigger the fast-start algorithm when emerging from sleep mode
6 bias_lut_after_sleep R/W 0 1: Do single bias LUT lookup when emerging from sleep mode
5 faststart_after_txdisable R/W 0 1: Trigger the fast-start algorithm when tx_disable deasserted
4 bias_lut_after_txdisable R/W 0 1: Do single bias LUT lookup when tx_disable deasserted
3
2 apc_enable R/W 0 1: Closed-loop operation. 0 => open-loop operation
1 faststart_enable R/W 0 1: Trigger the fast-start algorithm after power-on reset
0 bias_lut_enable R/W 0 1: Do single bias LUT lookup after power-on reset (apc_enabl e = 1)
1: Periodic lookups (apc_enabl e = 0).
0: No lookups from bias LUT
Maxim Integrated 41
A4h tx_apc The APC delay register controls the delay between the deassertion of l aser
shutdown and the activation of the APC loop counter. The APC loop gain sets the
gain (and thus the bandwidth) of the APC control loop.
BIT FIELD NAME TYPE POR
DESCRIPTION
7–4 apc_delay R/W 0000
0000: 0μs
0001: 128μs
0010: 256μs
0011: 384μs
:
1110: 1792μs
1111: 1920μs
3–0 apc_loop_gain R/W 1000
0000: 2-15
0001: 2-14
0010: 2-13
:
1101: 2-2
1110: 2-1
1111: 1
A5h tx_apc_target TYPE POR This is the MPD current target level for both the APC loop and the fast-start
algorithm.
R/W 00h
A6h tx_biasdac0 TYPE POR Bits 7 -0 of the 10-bit value which controls the bias current. The default is non-zero
so that there is sufficient current for the loop fault detect circuits to operate
correctly.
R/W 28h
A7h tx_biasdac1
BIT FIELD NAME TYPE POR DESCRIPTION
7–2 Undefined
1–0 tx_biasdac R/W 00 Bits 9-8 of the 10-bit value which controls the bias current
A8h tx_bias_threshold TYPE POR If tx_biasdac<9-2> exceeds tx_bias_threshold then the excess i ve_bias bit is
set in system_status.
R/W FFh
A9h tx_mon_bandwidth Determines the bandwidth of t he first order di gital lowpass fil ter which is applied
by the power monitoring circuit to the measured value of MPD current.
BIT FIELD NAME TYPE POR DESCRIPTION
7–4 Undefined
3–0 mon_bandwidth R/W 1000
0000: 311Hz
0001: 622Hz
1000: 80kHz
1110: 5.1MHz
1111: No filtering
AAh tx_fstart_initial TYPE POR Determines the initial step size of the fast-start algorithm.
R/W 80h
Maxim Integrated 42
ABh tx_fstart_decay Determi nes t he multiplic at i on factor applied t o the step size on each step of the
fast-s tart algorithm after the MPD current first exceeds the t arget threshold.
BIT FIELD NAME TYPE POR
DESCRIPTION
7–2 fstart_decay R/W 100101
100000: 32/64 = 0.5
100001: 33/64 = 0.516
100010: 34/64 = 0.531
100011: 35/64 = 0.547
100100: 36/64 = 0.563
100101: 37/64 = 0.5785
..
101110: 46/64 = 0.719
101111: 47/64 = 0.734
1–0
Undefined
ACh tx_fstart_duration Det erm i nes t he duration of the fast-st art algori thm (an iteration is 4 cycles of the
64 MHz system clock) and whether the laser is shut down for one or two cycl es
afterwards while the modulation control circuits settle.
BIT FIELD NAME TYPE POR DESCRIPTION
7 fstart_recovery_en R/W 1 1: Briefly shut down bias and modulation after the fast-start algori t hm
6 fstart_recovery_time R/W 0 0: Shut down for single iteration, 1: Shut down for 2 iterations
5–0 fstart_duration R/W 001111 T he f ast -start algori thm runs for a number of iterations specifi ed by this regist er.
ADh txsd_config Configures the TX signal detect feature.
BIT FIELD NAME TYPE POR DESCRIPTION
7–4 txsd_rogueonu_delay R/W 0011 The delay (in 64MHz clock cycles) between the fal ling edge of BEN and the
testing for rogue ONU.
3–2 txsd_threshold R/W 00
MPD current level above which signal is detect ed during burs ts and rogue ONU is
detected during gaps.
00: 20μA
01: 40μA
10: 60μA
11: 80mA
1 Undefined
0 Undefined
AEh txsd_deglitch_period
TYPE POR
The approximate time between the loss of transmitted signal and the deassertion
of TX_SD during a burst:
00h: 16ns to 31ns
01h: 31ns to 62ns
02h: 46ns to 92ns
a: b to c
b = (a + 1) x 15.625ns c = 2b
R/W 02h
Maxim Integrated 43
AFh ls_txfault_faulten Enables the fault conditions associated with the tx_fault laser safet y system
BIT FIELD NAME TYPE POR DESCRIPTION
7 Alarm R/W 1 1: Enable this fault condition for the tx_fault laser safety system
6 rogue_onu R/W 1 1: Enable this fault condition for the tx_fault laser safety system
5 soft_tx_fault R/W 1 1: Enable this fault condition for the tx_fault laser saf et y system
4 tx_disable R/W 0 1: Enable this fault condi tion f or the tx_fault laser safety system
3 Vdd R/W 1 1: Enable this fault condition for the tx_fault laser saf et y system
2 Vref R/W 1 1: Enable this fault condition for the tx_fault laser safety system
1 Apc R/W 1 1: Enable this fault condition for the tx_fault laser safety system
0 Bias R/W 1 1: Enable this fault condition f or the tx_fault laser safety system
B0h ls_txfault_latchen Latches the fault conditions associated with t he tx_fault l aser saf et y system
BIT FIELD NAME TYPE POR DESCRIPTION
7 Alarm R/W 1 1: Enable latching for this fault condition
6 rogue_onu R/W 1 1: Enable latching for this fault condition
5 soft_tx_fault R/W 0 1: Enable latc hing f or this fault conditi on
4 tx_disable R/W 0 1: Enable latching for this fault condition
3 Vdd R/W 1 1: Enabl e l atc hing for this fault condit i on
2 Vref R/W 1 1: Enable l atc hing for this fault c onditi on
1 Apc R/W 1 1: Enable l atc hing for this fault c onditi on
0 Bias R/W 1 1: Enable latching for this fault condition
B1h ls_shutdown_faulten Enables the fault conditions associated with the shut down laser safety system
BIT FIELD NAME TYPE POR DESCRIPTION
7 Alarm R/W 1 1: Enable this fault condition for the shutdown laser saf ety syst em
6 rogue_onu R/W 1 1: Enable this fault condition for the shutdown lase r safety sy s tem
5 soft_tx_fault R/W 0 1: Enable this fault condition for the shutdown laser safety syst em
4 tx_disable R/W 1 1: Enable this fault condi tion f or the shutdown laser safety system
3 Vdd R/W 1 1: Enable this fault condition for the shutdown laser safety system
2 Vref R/W 1 1: Enable this fault condition for the shutdown laser safety system
1 Apc R/W 1 1: Enable this fault condition for the shutdown laser safety system
0 Bias R/W 1 1: Enable this fault condition f or the shutdown laser safety system
Maxim Integrated 44
B2h ls_shutdown_latchen Latches the fault conditions associated with t he shut down laser safety system
BIT FIELD NAME TYPE POR DESCRIPTION
7 Alarm R/W 1 1: Enable latching for this fault condition
6 rogue_onu R/W 1 1: Enable latching for this fault condition
5 soft_tx_fault R/W 0 1: Enable latching for this fault condition
4 tx_disable R/W 0 1: Enable latching for this fault condition
3 Vdd R/W 1 1: Enable latching for this fault conditi on
2 Vref R/W 1 1: Enable latching for this fault condition
1 Apc R/W 1 1: Enable latching for this fault condition
0 Bias R/W 1 1: Enable latching for this fault condition
B3h ls_alarmflag_en Controls which of the DDM alarm flags contribute to the laser safety alarm_fault
fault condition.
BIT FIELD NAME TYPE POR DESCRIPTION
7 temp_hifault_en R/W 0 1: Alarm fault occurs when temp exceeds high temp threshold
6 temp_lofault_en R/W 0 1: Alarm fault occurs when temp below low temp threshold
5 supply_hifault_en R/W 0 1: Alarm fault occurs when supply exceeds high supply threshold
4 supply_lofault_en R/W 0 1: Alarm fault occurs when supply below low supply threshold
3 bias_hifault_en R/W 0 1: Alarm fault occurs when bias exceeds high bias t hreshold
2 bias_lofault_en R/W 0 1: Alarm fault occurs when bias below low bias threshold
1 txpower_hifault_en R/W 0 1: Alarm fault occ urs when txpower exceeds high txpower threshol d
0 txpower_lofault_en R/W 0 1: Alarm fault occ urs when txpower below low txpower threshold
B4h adc_filter
The samples of supply and rxpower may be lowpass filtered using a filter with
programmabl e bandwidth.
00: fs/(2 x pi x 64) = 0.25Hz
01: fs/(2 x pi x32) = 0.5Hz
10: fs/(2 x pi x16) = 1Hz
11: fs/(2 x pi x 8) = 2Hz
fS = 100Hz based on measurements every 10ms.
BIT FIELD NAME TYPE POR DESCRIPTION
7–6 Undefined
5–4 rxpower_bandwidth R/W 00 Selects rxpower filter bandwidth
3–2 supply_bandwidth R/W 00 Selects supply fi lter bandwidth
1–0 Undefined
B5h adc_config Configure the ADC
BIT FIELD NAME TYPE POR DESCRIPTION
7–6 Undefined
5–4 adc_supplysel R/W 00 00: VDD_TX 10: VDD_RX
01: VDD_TXO 11: VDD_RXO
3–0 Undefined
Maxim Integrated 45
B6h temp_config Configures the temperature senso r
BIT FIELD NAME TYPE POR DESCRIPTION
7 temp_ext_sensor R/W 0 1: Use external sensor, 0: Use internal sensor
6 R/W 11 Reserved
5 leave_PU R/W 1 0: Enable tempsense_pu
4–0 Undefined
B7h main_config Selects the operations performed when the main loop is enabled. Operations are
performed once per iteration of the loop.
BIT FIELD NAME TYPE POR DESCRIPTION
7 biaslut_en R/W 1 1: Load tx_biasdac register for m the bias LUT
6 sff_en R/W 1 1: Recalculate sff-8472 DDMs
5 Undefined
4 trackinglut_en R/W 1 Power m oni t or uses values from the tracking LUT
3 apdlut_en R/W 1 1: Load the rx_apddac, rx_apdpwm or rx_apd_target register from the APD
LUT
2 modlut_en R/W 1 1: Load the tx_moddac register from the modulation LUT
1 Undefined
0 mainloop_en R/W 0 1: Enable the main loop
B8h sleep_config Configures Sleep mode
BIT FIELD NAME TYPE POR DESCRIPTION
7–6 Undefined
5 Reserved
4 rx_respond_to_sleeppin R/W 0 1: Power down Rx when SLEE P pin asserted, 0: Ignore SLEEP pin
3–2 Undefined
1 Reserved
0 tx_respond_to_sleeppin R/W 0 1: Power down Tx when SLEEP pin asserted, 0: Ignore SLEEP pin
B9h temp_calibrate Used during calibration of temperature sensor
BIT FIELD NAME TYPE POR DESCRIPTION
7–6 Undefined
5–0 temp_calibrate R/W 011111 Calibration trim register
BAh rx_power_threshold
TYPE POR The threshold that defines which pair of Rx Power calibration constants is used. If
the 3-slope encoded sam pl e of rx power is above this threshold then select
rxpower_slope1 and rxpower_offset1. Otherwise select rxpower_slope0 and
rxpower_offset0.
R/W FFh
Maxim Integrated 46
BEh pin_config0 Pin function and polarity configuration
BIT FIELD NAME TYPE POR DESCRIPTION
7 Undefined
6 dac_select R/W 1 1: DAC pin 39, 0: TX_FAULT pin 39
5 txsd_select R/W 0 1: TX_SD pin 21, 0: TX_FAULT pin 21
4 txfault_invert R/W 0 1: Invert the signal to TX _FAULT pin, 0: No inversi on
3 los_invert R/W 0 1: LOS pin = 1 when signal detected and LOS pin = 0 when no signal
0: LOS pin = 1 when no signal detected and LOS = 0 when signal
2 R/W 0 Reserved
1 R/W 0 Reserved
0 tx_disable_invert R/W 0 1: Signal f rom TX_DISABLE pin is inverted, 0: No inversion
BFh pin_config1 Masks outputs which should remain quiet during initi alization
BIT FIELD NAME TYPE POR DESCRIPTION
7–4 Undefined
3 apd_inhibit R/W 1 1: APD_CTRL disabl ed (= Hi-Z), 0: Normal function
2 txsd_allow R/W 0 0: TX_SD disabled (= 1), 1: Normal function
1 los_inhibit R/W 1 1: LOS disabled (= 1), 0: Normal function
0 laser_inhibit R/W 1 1: TX_OUT and BIAS are shutdown, 0: Normal function
C0h software_faults This register is used to set fault conditions via the TWI
BIT FIELD NAME TYPE POR DESCRIPTION
7–1 Undefined
0 soft_tx_fault R/W 0 1: Asserts the soft_tx_fault laser safety fault condition
C1h temp_control C onfigures the te mperature sensor
BIT FIELD NAME TYPE POR DESCRIPTION
7–6 Undefined
5 tempsense_pu R/W 1 0: temperature sensor powers down between reads
4–0 Undefined
E0h initialization_status Reports status associated with device initializati on
BIT FIELD NAME TYPE POR DESCRIPTION
7 E 0 Reserved
6 Undefined
5 eeprom_dma_idle R 0 1: EEPROM is idle and may be accessed
4 R 1 Reserved
3 tx_powerup_done R 0 1: Tx path power up during initialization is complete
2 rx_powerup_done R 0 1: Rx path power up during initialization is co mplete
1 eeprom_data_invalids R 0 1: Data integrity check failed during initialization
0 eeprom_unresponsive R 0 1: EEPROM failed to ACK the slave address during initialization
Maxim Integrated 47
E1h ls_fault_status Report s real time stat us of fault conditi ons at input to the laser safety syst em
BIT FIELD NAME TYPE POR DESCRIPTION
7 Alarm R 1: Fault condition currentl y exists
6 rogue_onu R 1: Fault condition currently exists
5 soft_tx_fault R 1: Fault condition currently exists
4 tx_disable R 1: Fault condition currentl y exists
3 Vdd R 1: Fault condition currently exists
2 Vref R 1: Fault condition currentl y exists
1 Apc R 1: Fault condition currentl y exists
0 Bias R 1: Fault condition currentl y exists
E2h ls_fault_events Rec ords when the fault conditi ons at the input to the laser safety system have
been asserted. Write ‘1’ to these bits to clear back to ‘0’
BIT FIELD NAME TYPE POR DESCRIPTION
7 Alarm E 1: F ault condition has occurred
6 rogue_onu E 1: Fault condition has occurred
5 soft_tx_fault E 1: Fault condition has occurred
4 tx_disable E 1: Fault conditi on has occ urred
3 Vdd E 1: Fault conditi on has occ urred
2 Vref E 1: Fault conditi on has occ urred
1 Apc E 1: Fault conditi on has occ urred
0 Bias E 1: Fault conditi on has occ urred
E4h hardware_status Reports the real-tim e status of selected di gital pins
BIT FIELD NAME TYPE POR DESCRIPTION
7–5 Undefined
4 txsd_pin R Indicates the status of the TXSD pin
3 tx_fault_pin R Indicates t he status of the TX_FAULT pin
2 Shutdown R Indi cates the status of the internal shutdown signal
1 sleep_pin R Indicates the status of the SLEEP pin
0 tx_disable_pin R Indicates the status of the TX_DISABLE pin
E6h temperature_uncal TYPE POR The temperat ure sample value before calibration
R
Maxim Integrated 48
E7h supply_uncal TYPE POR The supply sample value before calibration
R
E8h bias_uncal TYPE POR The bias sample value before calibration
R
E9h txpower_uncal TYPE POR The tx_power value before re-ranging and calibrat i on
R
EAh rxpower_uncal TYPE POR The rxpower sampl e val ue before calibration
R
EBh apdadc_uncal TYPE POR The uncalibrated measure of APD voltage
R
Maxim Integrated 49
Simplified Interface Models
LOS,
TX_SD
V
DD
V
CC
MPD
V
DD
BIAS
V
DD
50
50
RX_IN+
RX_IN-
V
DD
V
CM
5050
V
DD
V
DD
RX_OUT+
RX_OUT-
TX_OUT+/-
TX_IN+
TX_IN-
V
DD
V
DD
16k
V
DD
24k
5k
V
DD
16k
V
DD
24k
5k
Figure 27. Interface Diagrams
Maxim Integrated 50
ONU Application Diagra m s
82
VCC
130
82
VCC
130
TX_IN+
BEN+
TX_IN-
BEN-
VDD
VDD
16k
VDD
24k
5k
VDD
16k
VDD
24k
5k
Figure 28. LV PE CL Ext ern al Term in ati ons
100
V
CC
V
CC
50
50
TX_IN+
BEN+
TX_IN-
BEN-
V
DD
V
DD
16k
V
DD
24k
5k
V
DD
16k
V
DD
24k
5k
Figure 29. C ML Exter n al Ter minati ons
Maxim Integrated 51
Package Information
For the latest package outline information and land patt erns (footprints) , go to www.maximintegrated.com/packages. Note that a “+”,
“#”, or “-” in the package code indicates RoHS status only. P ackage drawi ngs may show a dif ferent suffix charac ter, but the drawing
pertai ns to the package regardless of RoHS status.
PACKAGE TYPE PACKAGE CODE OUTLINE NO. LAND PATTERN NO.
40 TQFN-EP T4055+2 21-0140 90-0002
Maxim Integrated 52
Revision History
REVISION
NUMBER REVISION
DATE DESCRIPTION PAGES CHANGED
0 11/12 Initi al releas e
1 7/13 Made corrections to Pin Description , F i gure 15, 94h regist er table 10, 24, 39
2 2/14 Made corrections to Pin Description , apc l oop bandwi dt h section, Figure 15,
mismatch font, mpd_range section, Register Map secti on, Fi gure 29, and bold
typeface for register table headings
10, 12, 20, 21, 25
29, 3649, 50, 52
53
Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses
are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits)
shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance.
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